Fluidic masking

ABSTRACT

IN MAKING A TARGET FOR A TELEVISION CAMERA TUBE, IT IS NECESSARY TO THIN THE BACKSIDE OF A SEMICONDUCTIVE SUBSTRATE, WHICH IS OPPOSITE A FACE HAVING A DIODE ARRAY THEREON. TO THIN THE SUBSTRATE, IT IS POSITIONED FACE DOWN ON A FLLUID NONDELETERIOUS TO THE SUBSTRATE AND DIOD ARRAY. THE FLUID IS CONTAINED IN A CAVITY OF A HOLDING DEVICE. THE POSITIONING IS SUCH THAT THERE IS NO SPACE BETWEEN THE FLUID AND THE SUBSTRATE. AN APERTURED TOP MEMBER IS THEN MOUNTED ON THE SUBSTRATE AND THE HOLDING DEVICE TO RETAIN THE SUBSTRATE ON THE FLUID. THE ASSEMBLY OF THE HOLDING DEVICE AND TOP MEMBER WITH THE SUBSTRATE THEREBETWEEN IS IMMERSED AND ROATED IN AN ETCHANT TO THIN THE BBACKSIDE OF THE SUBSTRATE THROUGH THE APERTURE OF THE TOP MEMBER. THE FLUID PROVIDES A TIGHT SEAL ON THE FACE OF THE SUBSTRATE TO PREVENT THE ETCHANT FROM DAMAGING SUCH FACE AND THE DIODE ARRAYL THEREON A VENT EXTENDING FROM THE CAVITY OF THE HOLDING DEVICE TO ITS OUTER EDGE ASSIST IN THE SUBSEQUENT REMOVAL OF THE SUBSTRATE FROM THE CAVITY.

H. A. HETRICH FLUIDIC MASKING July 9, 1974 3 Sheets-Sheet '1 OriginalFiled June 7, 1971 FIG-3 y 9, 1974 H. A. HETRICH 3,823,048

FLUIDIC msxms Original Filed June 7, 1971 3 Sheets-Sheet 2 H. A; HETRICHFLUIDIC HASKING July 9, 1974 5 Sheets-Sheet 5 Original Filed June '7,1971 3,823,048 FLUIDIC MASKING Harold Arthur Hetrich, Reading, Pa.,assignor to Western Electric Company, Incorporated, New York, N.Y.Original application June 7, 1971, Ser. No. 150,345, now

Patent No. 3,701,705. Divided and this application Aug.

15, 1972, Ser. No. 280,905

Int. Cl. H011 7/50 US. Cl. 156-345 7 Claims ABSTRACT OF THE DISCLOSUREIn making a target for a television camera tube, it is necessary to thinthe backside of a semiconductive substrate, which is opposite a facehaving a diode array thereon. To thin the substrate, it is positionedface down on a fluid nondeleterious to the substrate and diode array.The fluid is contained in a cavity of a holding device. The positioningis such that there is no space between the fluid and the substrate. Anapertured top member is then mounted on the substrate and the holdingdevice to retain the substrate on the fluid. The assembly of the holdingdevice and top member with the substrate there- -between is immersed androtated in an etchant to thin the backside of the substrate through theaperture of the top member. The fluid provides a tight seal on the faceof the substrate to prevent the etchant from damaging such face and thediode array thereon. A vent extending from the cavity of the holdingdevice to its outer edge assists in the subsequent removal of thesubstrate from the cavity.

This is a division, of application Serial No. 150,345 filed June 7,1971, now Pat. 3,701,705.

BACKGROUND OF THE INVENTION Field of the Invention This inventionrelates to apparatus for masking a workpiece, and more particularly, toapparatus for making diode-array targets from semiconductive substratesfor electron-beam charge-storage devices such as television cameratubes.

DESCRIPTION OF THE PRIOR ART This invention is particularly suited foruse in the manufacture of semiconductive devices or the like. An exampleof such semiconductive devices are silicon targets having arrays oflight-sensitive photo diodes for the storage of electron-beam charges,such as those disclosed in Reynolds Pat. 3,011,089 and Buck et al. Pats.3,403,284 and 3,458,782.

While the invention is adapted to be used in conjunction with themasking of a number of different kinds of workpieces, it will beparticularly described with respect to masking semiconductivesubstrates. These substrates are advantageously used in makingdiode-array targets for electron-beam charge-storage devices such astelevision camera tubes. The diode-array target is basically a flatsemiconductive substrate having a closely spaced array of p-n junctionsnear one surface.

In fabricating the diode-array target in accordance with prior arttechniques, an n-type substrate is prepared by sawing it from a siliconcrystal ingot and then etching and polishing it. After a carefulcleaning, a layer of silicon dioxide is formed over the entiresubstrate.

Next, a photoresist material is deposited on the face of the substrateand a fluid is directed on its backside. The substrate is then spun tocoat evenly the face, while the fluid prevents the photoresist materialfrom coating the backside. (See, e.g., co-pending application, Ser. No.95,821, filed on Dec. 7, 1970 by L. F. Boyer and A. F.

United States Patent 'ice Johnson, Jr., assignors to Western ElectricCo., Inc. and now issued into Pat. 3,695,928.) The substrate is thenexposed with the required diode-array pattern and developed to formapertures in the photoresist material. Etching of the substrate throughthese apertures follows to produce corresponding apertures in thesilicon dioxide layer. Through the apertures in the silicon dioxidelayer, boron is diffused to form p-type regions, with the dioxide layeracting as a diffusion mask. These p-type regions in the n-type substrateform the diode array on one sid of the substrate.

Following the formation of the diode array, the substrate is subjectedto a thinning operation involving numerous process steps. First, wax(such as that sold under the trademark Apiezon) is applied to a sapphiresuporting disc heated by a hot plate. In applying the wax an opening isleft in the center of the disc for subsequent optical measurements forascertaining the progression of the thinning of the substrate. Thesubstrate is then placed on top of the waxed disc with the array sidefacing down and carefully centered. The assembly of the disc, wax andsubstrate is then removed from the hot plate and allowed to cool,leaving the substrate held to the disc by the wax.

Using a rotating tool, a rim of wax in a solvent is applied to thebackside of the substrate using a small brush. After the wax dries, thecentral portion of the backside of the substrate is subjected to anetching operation wherein the substrate is immersed in an etchant androtated therein for a period sufiicient to thin the substrate down to apredetermined thickness. This thickness is considerably less than thediffusion length of minority carriers generated by absorbed light in theultimate target and limits the amount of lateral diffusion of minoritycarriers in order to obtain high resolution in the target.

After the thinning, the substrate is rinsed, blown dry and opticallymeasured. The substrate is then removed from the supporting disc byplacing the assembly on the hot plate to soften the wax. The slice ismechanically slid off the sapphire disc and placed in three successivehot trichloroethylene baths and then in a boiling trichloroethylenesolution followed by an alcohol soak and water rinse. This results inthe removal of all traces of wax.

After the removal of the substrate from the disc, it is subjected toseveral finishing heat treatments. The first of these treatments is ashallow phosphorous diffusion to improve the blue sensitivity of theultimate camera tube and to reduce its dark current. Next, the borondiffusion glass, which has been left on the array side of the substrateup to this point to protect it against phosphorous diffusion, is removedto expose the p-type regions of the diodes. At the same time that theboron diffusion glass is removed, the phosphorous diffusion glass isalso removed.

Next, the substrate is'annealed in hydrogen at a low temperature tofurther reduce the dark current of the ultimate camera tube. Finally, aresistive film is evaporated over the diode array and it is ready forevaluation. (See Crowell et al. Pat. 3,419,746.)

The holding of the substrate in place with the wax and the otherprocessing steps necessitated by the wax results in a messy,time-consuming process involving numerous process steps. These steps donot lend themselves to high-volume production. In addition, there are anumber of impurities found in the wax, such as iron, magnesium andcalcium. These impurities often lead to the contamination of theultimately formed diode-array target.

In fabricating the diode array target, it is desirable to eliminate asmany process steps as possible, especially the wax step. One prior arttechnique of eliminating the waxing step is to use a mechanical maskheld to the slice by magnetic facilities. However, difliculty wasexperienced with this as a result of the etchant leaking to the arrayside of the substrate and rendering defective the ultimately fabricatedtarget.

It is also desirable in the thinning operation, which results in theremoval of about 90% of the material at the central portion of thesubstrate, that the removal take place in a controlled and uniformmanner. This is because irrgular etching results in high spots, holes,depressions and other surface non-uniformities, which render defectivethe ultimately fabricated diode-array tar et.

g SUMMARY OF THE INVENTION It is, therefore, an object of this inventionto provide new and improved apparatus for masking a workpiece.

A further object of this invention is to provide an apparatus forprotecting a workpiece from a deleterious substance.

Another object of this invention is the provision of improved apparatusfor making a charge-storage device from a semiconductive substrate.

A further object of this invention is to provide an apparatus forselectively thinning a portion of a substrate.

With these and other objects in view, the present invention contemplatesan apparatus for masking a workpiece. The apparatus includes a devicehaving a cavity containing a fluid upon which the face of the workpieceis positioned to leave no space between the face of the workpiece andthe fluid. An apertured member is positioned over the backside of theworkpiece and retains the workpiece in the cavity whereby the face and aportion of the workpiece are masked by the fluid and the member.

BRIEF DESCRIPTION OF THE DRAWINGS Other objects and advantages of thepresent invention may be more clearly understood by reference to thefollowing detailed description and the accompanying drawings, wherein:

FIG. 1 is an enlarged perspective view, having a cutout section, of afabricated diode-array target;

FIG. 2 is a greatly enlarged perspective view, partially in section, ofthat portion of the target of FIG. 1 enclosed in a phantom circle,illustrating sectional details of the target;

FIG. 3 is an enlarged perspective view of an apparatus, partiallyassembled, for masking a substrate to selectively thin a portion of itsbackside;

FIG. 4 is a sectional view of a portion of the apparatus of FIG. 3,taken along the lines 4-4 of FIG 3, showing a fluid from a sourcedeposited in a cavity of a holding device;

FIG. 5 shows the holding device of FIG. 4 with facilities for exerting aforce on the backside of the substrate to force the quantity of fluidexceeding the volume of the cavity to flow out of the cavity.

FIG. 6 shows the holding device of FIG. 4 with a resilient, aperturedtop member force fitted thereover;

FIG. 7 shows an etching mechanism including facilities for rotatingsubstrates in an etchant to thin the substrates;

FIG. 8 shows facilities for optically checking the thickness of athinned substrate; and

FIG. 9 shows facilities for removing the substrates from the cavity andfluid therein.

DETAILED DESCRIPTION Diode-array-target Referring now to the drawingsand in particular to FIGS. 1 and 2, a diode-array target, designatedgenerally by the numeral 11, is shown. The target 11 includes an n-typesemiconductive substrate 12 (FIG. 2), preferably formed of silicon,having a layer 13 of silicon dioxide formed on the surface or face 14thereof. Through the layer 13 a plurality of apertures 16 are formed.Corresponding to these apertures 16 are a plurality of p-type regions 17which are formed through the apertures 16 and on the face 14 of thesubstrate 12. The p-type regions 17 together with the n-type substrate12 form an array of light-sensitive photo diodes.

The substrate 12 has an extremely thin central portion 18 formed throughits backside, designated generally by the numeral 19, for reducing thedistance minority carriers must travel to the diodes on the oppositeface 14 of the substrate 12 and for limiting the lateral diffusion ofthese carriers. The substrate 12 also includes a relatively thick rim 21on the periphery of the backside 19 for supporting the substrate 12.

The diode-array target 11 is advantageously used in a television cameratube. In so using the target 11, the light being sensed impinges on thecentral portion 18 of the backside 19 of the substrate 12. This producesminority carriers that travel to the diode array on the opposite face14, while an electron beam from a cathode (not shown) scans the diodearray on the face 14.

Typically, the substrate 12 has the configuration of a disc with adiameter of about 850 mils and with the central portion 18 being about760 mils in diameter and about 0.6 mils thick. The rim 21 typically isabout 5 mils thick. Usually there are about 1,000,000 individual diodesin the array on the face 14 of the substrate 12, and about 650,000 ofthese are used when the target 11 is mounted in a television cameratube. Obviously, the relative proportions in FIGS. 1-9 have beenexaggerated to more clearly illustrate the target 11, and the presentinvention.

FABRICATING METHOD In fabricating the target 11 of FIGS. 1 and 2, thediode array is formed on the face 14 of the substrate 12, as previouslyexplained. Then, the backside 19 of the substrate 12 is subjected to athinning operation to form the central portion 18.

Depositing Fluid To carry out the thinning operation, a quantity of afluid 28 (FIG. 4) from a source 29 is deposited in a cavity 31 of aholding device 32 (FIGS. 3 and 4). Preferably, the device 32 is formedof material such as that sold under the trademark Teflon or the like.

The quantity of the fluid 28 deposited in the cavity 31 exceeds itsvolume and forms a meniscus 34 at the top of cavity 31. The fluid 28 maybe any fluid that has a nondeleterious effect on the substrate 12 andthe holding device 32 and preferably is deionized water.

Positioning and Forcing Substrate Next, the face 14, having the diodearray thereon, of the substrate 12 is positioned on the meniscus 34 ofthe fluid 28. Using a device that will not damage the substrate 12, suchas a plastic rod 38 (FIG. 5) having a tapered end 39, a force is thenexerted on the backside 19 of the substrate 12.

The force of the rod 38 causes the quantity of the fluid 28 exceedingthe volume of the cavity 31 to flow out of the cavity 31 and also seatsthe substrate 12 in a counterbore 40 of the holding device 32. Althoughmost of the excess fluid 28 flows over a circumferential edge 41 of theholding device 32, some of it also flows out of a vent 42 in the device32 that extends from the cavity 31 to the edge 41. The vent 42 has adiameter small enough so that surface tension prevents the fluid 28 fromdrawing from the cavity 31, except when the force is exerted on thebackside 19 of the substrate 12 and transmitted to the fluid 28. Whenthe force is so exerted, only a small quantity of the fluid 28 is forcedfrom the cavity 31 through the vent 42 and there is still enough fluid28 remaining in the cavity 31 so as to leave no space between the face14 and the fluid 28 and to thereby mask the face 14 with the fluid 28.The force on the backside 19 also eliminates the meniscus 34.

Mounting Top Member After the exertion of the force on the backside 19of the substrate 12, a top member 46 (FIGS. 3 and 6) is mountedremovably on the holding device 32. The member 46 is formed of aresilient material such as that sold under the trademark Teflon or thelike.

An aperture 47 is formed in the top member 46, preferably by forcefitting a washer 49 (FIGS. 3 and 6) in a central opening 51 of the topmember 46, as shown in FIG. 6. Typically, the washer 49 is formed of amaterial such as sapphire or the like.

The mounting of the top member 46 positions a portion 52 of the bottomsurface of the washer 49 that is adjacent the aperture 47 to overlapthat portion of the backside 19 of the substrate 12 that will form thesupporting rim 21 (FIG. 2) after a subsequent etching operation. The topmember 46 also presses the overlapping surface of the washer 49 againstsuch portion of the backside 19 to mask this portion. The mounting ofthe top member 46 also closes the vent 42.

To effect a force fit between the top member 46 and the holding device32, the internal diameter 53 of the member 46 is made slightly smaller(by an amount equal to about 6 mils in diameter) than the externaldiameter of the circumferential edge 41 of the holding device 32. Ofcourse, it should be understood that the top member 46 may also bethreaded to the device 32 or other securing facilities may be used tomount removably the top member 46 to the holding device 32.

Etching Next, an assembly, designated generally by the numeral 55 (FIGS.6 and 7) of the holding device 32 with the top member 46 mounted thereonand with the substrate 12 therebetween and a plurality of other similarassemblies 55 are individually and removably mounted on a plurality ofspur gears 57 (FIG. 7). In mounting the assemblies 55 on the gears 57,stepped portions 58 (FIGS. 4-6) of the holding device 32 are forcefitted into associated depressions (not shown) on the top surfaces ofthe gears 57.

The gears 57 are arranged in groups so that three of such gears 57engage each other, and one of such gears 57 of each group engages alarger central spur gear 61. The gears 57 and 61 are rotatably mountedto a circular platform 62 and, in addition, the gear 61 is fixed to ashaft 64.

After the assemblies 55 are mounted on the gears 57, by the use of theshaft 64 the assemblies 55, the gears 57 and 61, and the platform 62 areimmersed in an etchant 67 contained in a tank 68 fixed to a base 69.Typically, the etchant 67 is a mixture of acetic acid saturated withiodine and hydrofluoric and nitric acids or equivalent.

Upon the immersion of the asemblies 55, the etchant 67 removes throughthe aperture 47 of the top member 46 small quantities of material fromthe backside 19 of each substrate 12 to thin them and eventually formthe thin central portions (FIG. 2) in the substrates 12.

A conventional motor 72 mounted by a bracket 73 to the base 69 rotatesthe shaft 64 through a standard gear box 74. Rotation of the shaft 64rotates the central gear 61, which thereby rotates the gears 57 abouttheir own axes. Tpically, the gears 67 with the assemblies 55 thereonare rotated at about 60 to 120 rpm.

Rotation of the shaft 64 also rotates a paddle 76 to continually stirthe etchant 67 to aid in maintaining the temperature of the etchant 67uniform. Rotating the assemblies 55 imparts, of course, the same motionto the substrate 12 in the etchant 67. This motion coupled with theuniformity of temperature of the etchant 67 tends to bring about a moreuniform removal of material from the backsides 19 in the thinningoperation.

Due to the fluid 28 in the cavity 31 of the holding device 32, theabsence of a space between the substrate 12 and the fluid 28 and theclosing of the vent 42 by the top member 46, the face 14 with the diodearray thereon is tightly sealed from the etchant 67 as well as itsfumes. This results in a high degree of protection of the face 14 of thesubstrate 12. This protection is extremely important because damage tothe 650,000 diodes in the array on the face 14 is likely to render thetarget 11 defective, and at this stage of the fabrication of the target11, a substantial investment in processing time and materials hasalready been made in the target. Significantly, this protection iseifectuated without the messy and time consuming waxing steps of theprior art.

The backside 19 of the substrate 12 is not as critical and as easilydamaged as its face 14 which has the diode array thereon. Accordingly,the washer 52 which is pressed against substrate 12 by the top member 46adequately masks and protects from the etchant 67 the portion of thebackside 19 that will be the supporting rim 21 (FIG. 2) of the substrate12. The rim 21 is formed as a result of the etching of the substrate 12.

Except for the substrate 12, all of the elements that are immersed in orcontain the etchant 67 are resistant to it. These elements include theholding device 32, the top member 46, the washer 49, the gears 57 and61, the platform 62, the shaft 64, the paddle 76, and the tank 68.

Optical Checking After thinning, the substrates 12, the platform 62along with the gears 57 and 61 and the assemblies 55 are lifted by theshaft 64 and removed from the etchant 67. Then, one of the assemblies 55is placed on a slotted table 79 (FIG. 8) of an optical checkingapparatus, designated generally by the numeral 81.

The apparatus 81 includes a conventional infrared light source 83energized by a conventional power supply 85. The source 83 passesinfrared radiation through a disc 87 (FIGS. 3-6) which is transparent tosuch radiation. The disc 87, typically formed of sapphire, is forcefitted into a central aperture 89 of the holding device 32. The

radiation also passes through the fluid 28 which is transparent to suchradiation.

Depending on the thickness of the central portion 18 of the substrate12, such substrate 12 passes a certain amount of the radiation. Thisradiation is sensed by a conventional infrared radiation detector 91which displays the amount of radiation so sensed on a device 92. Sincethe amount of radiation passing through the substrate 12 is directlyproportional to the thickness of such substrate 12, the display device92 may be calibrated to read directly the thickness of the etchedsubstrate 12. If the device 92 indicates that the substrate 12 has notbeen adequately thinned, the assembly 55 is removed from the table 79.Such assembly 55 is placed on the gear 57 from which it was removed, andit along with the other assemblies 55 are again immersed and rotated inthe etchant 67 for an additional period of time and the thickness of thesubstrate is again checked. i

On the other hand, if the device 92 indicates that the substrate 12 hasbeen adequately thinned, (typically to a thickness of about 0.6 mils)the assembly 55 is removed from the table 7 9.

Removing the Top Member and Substrate After the assembly 55 is removedfrom the table 79, if no additional thinning in the etchant 67 isnecessary, the top member 46 is removed from the outer edge 41 of theholding device 32. The removal of the top member 46 opens the vent 42that extends from the cavity 31 to the outer edge 41. The opening of thevent 42 permits atmospheric pressure to act on the cavity 31 through thevent 42 of the holding device 32.

Next, with the aid of a conventional vacuum pickup device 94 (FIG. 9),the substrate 12 is removed from the counterbore 40 of the holdingdevice 32 and from the fluid 28 of the cavity 31. The atmosphericpressure acting on the cavity 31 assists in the removal of the substrate12 by preventing a partial vacuum from forming between the substrate 12and the fluid 28.

Hence, the substrate 12 has been thinned and the fabrication of thediode-array target 11 (FIGS. 1 and 2) is now complete, and the target 11is now ready for evaluation with conventional electrical and mechanicaltests. The other substrates 12 of other assemblies 55 are similarlyremoved from the holding devices 32 and evaluated. While the inventionhas been described in connection with semiconductive substrates such asdiode-array targets, it is to be understood that the invention may alsobe used in connection with other articles.

It is to be further understood that the above-described arrangements aresimply illustrative of the application of the principles of thisararngement. Numerous other arrangements may be readily devised by thoseskilled in the art which embody the principles of the invention and fallwithin its spirit and scope.

What is claimed is: 1. An apparatus for masking a workpiece comprising:a device having a cavity for a fluid upon which the face of theworkpiece is positioned to leave no space between the face of theworkpiece and the fluid; and

an apertured member for retaining the workpiece in the cavity, wherebythe face and a portion of the backside opposite the face of theworkpiece are masked by the fluid and the member.

2. The apparatus of claim 1, wherein the fluid is water.

3. The apparatus of claim 1, wherein the cavity is filled with thefluid.

4. The apparatus of claim 1, wherein the cavity has a vent extendingtherefrom to the outer edge of the holding device, the vent having adiameter of such a size so as not to drain the fluid from the cavity.

5. The apparatus of claim 4, wherein the apertured member blocks thevent.

6. An apparatus for masking a workpiece, comprising:

a device having a cavity filled with a quantity of fluid exceeding thevolume of the cavity to form a meniscus of the fluid at the top of thecavity upon which the face of the workpiece is positioned;

means for exerting a force on the backside of the workpiece opposite itsface to force the quantity of fluid exceeding the volume of the cavityto flow out of the cavity to thereby eliminate the meniscus and leave nospace between the face and the fluid; and

a top member having an aperture therein mounted on the holding device toposition a portion of the bottom surface of the top member that isadjacent to overlap such backside of the workpiece, whereby the face ofthe workpiece and an annular area on the backside corresponding to theoverlapping surface of the aperture are masked.

7. The apparatus of claim 6, wherein the fluid is transparent toinfrared radiation.

References Cited UNITED STATES PATENTS 3,588,430 6/1971 Bronx et al.9636 X 2,820,312 1/1958 Coontz 156345 3,323,967 6/1967 Webb 1563453,494,791 2/1970 Eugster 156l7 X 3,695,928 10/1972 Boyer et al. 117-212WILLIAM A. POWELL, Primary Examiner US. Cl. X.R. 15616, 17

